Gluconacetobacter strain having cellulose producing activity

ABSTRACT

Disclosed herein is a novel  gluconacetobacter  strain having cellulose producing activity. Specifically, the present invention relates to a novel  gluconacetobacter  strain producing nano-structured cellulose in a highly efficient manner. The cellulose produced by the strain, due to its superb thermodynamic properties, can be characterized as nano-structured bacterial cellulose and therefore utilized as a bio-nano-fiber. Particularly, the cellulose can be impregnated with a resin to form a cellulose-based resin which can be effectively adapted for a substrate for a liquid crystal display (LCD).

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims priority to Korean Patent Application No. 10-2010-0018886, filed Mar. 3, 2010, and Korean Patent Application No. 10-2011-0010843, filed Feb. 8, 2011, and all the benefits accruing therefrom under 35 U.S.C. §119, which are hereby incorporated by reference for all purposes as if fully set forth herein.

BACKGROUND OF THE INVENTION

(a) Field of the Invention

The present invention relates to a novel gluconacetobacter strain having cellulose producing activity. Specifically, the present invention relates to a novel gluconacetobacter strain capable of producing nano-structured cellulose in a highly efficient manner.

(b) Description of the Related Art

Cellulose is one of the most abundant natural macromolecules on Earth with about 10¹¹ ton estimated to be naturally synthesized, most of which is biosynthesized to be the structural component of cell wall fibers of higher plants. Its high tensile strength is mainly due to its overall structure. Cellulose molecules form a chain or microfibril whose length ranges to 14,000 units, which in turn is structured into a twisted rope-shaped bundle maintained by hydrogen bonds. On the basis of its characteristics of being abundant and having unique physical properties, many studies with regard to its possible industrial applicability as a regenerating resource have been performed.

Since A. J. Brown reported in 1886 that Acetobacter produced cellulose, Bacterial Cellulose (BC) produced by a microorganism has become the subject of continuous studies as a new material. In particular, it has been discovered that microorganism-derived BC forms ribbon-like bundles, whereas plant-derived cellulose forms bundles of microfibrils.

In contrast to microfibril bundles formed by plant-derived cellulose, the ribbon-like bundles formed by microorganism-derived BC are produced in their pure state in the absence of lignin or hemicelluloses. The unique advantageous characteristics of BC such as high mechanical strength, high water absorption, high crystallizability, and biodegradability promote development of its diverse applications in a variety of industrial fields.

Currently, despite its high cost, s-glass has been selected as a suitable material for substrates of liquid crystal displays (LCDs) due to its properties, including low heat expansion coefficient, high permeability, and micro-thickness. It has been reported that LCD substrate thermodynamic properties can be enhanced relative to those of s-glass by using nano-structured cellulose, which can be produced by microorganisms. (Schraamm, M. and S. Hestrin. 1054. Factors affecting production of cellulose at the air/liquid interface of a culture of Acetobacter xylinum. J. Gen. Microbiol. 11:123-129). Therefore, it is desirable as well as cost-effective to develop a microorganism that is more efficient in producing cellulose.

Although it is well-known that acetobacter xylinum can produce BC, its inefficiency in production of cellulose has called for a novel organism that can replace it.

SUMMARY OF THE INVENTION

The present invention is directed to a novel gluconacetobacter strain effectively producing cellulose.

Therefore, disclosed herein is a gluconacetobacter sp. D44 strain having Accession No: KCCM11078P or gluconacetobacter intermedius D47 strain having Accession No: KCCM11079P which shows cellulose producing activity.

In an embodiment, a culture of the gluconacetobacter strain is also disclosed.

In an embodiment, a composition comprising at least one selected from the group consisting of the gluconacetobacter strain, a culture thereof, and a concentrate or a dried product of the strain or the culture is disclosed.

In an embodiment, a method of producing cellulose comprising the steps of: culturing the gluconacetobacter strain according to claim 1; and obtaining cellulose from the culture is disclosed.

In an embodiment, a method of producing a cellulose-based resin comprising the steps of: preparing the cellulose produced by the gluconacetobacter strain according to claim 1; and impregnating the cellulose with a resin is disclosed.

At least one of the above and other features and advantages of the present invention may be realized by providing a gluconacetobacter strain having Accession No: KCCM11078P or gluconacetobacter intermedius strain having Accession No: KCCM11079P which shows cellulose producing activity.

At least one of the above and other features and advantages of the present invention may be realized by the culture of gluconacetobacter strain.

At least one of the above and other features and advantages of the present invention may be realized by providing a composition comprising at least one selected from the group consisting of the gluconacetobacter strain, the culture thereof, and a concentrate or a dried product of the strain or the culture.

At least one of the above and other features and advantages of the present invention may be realized by providing a method of producing cellulose comprising the steps of: culturing the gluconacetobacter strain according to claim 1; and obtaining cellulose from the culture.

At least one of the above and other features and advantages of the present invention may be realized by providing a method of producing a cellulose-based resin comprising the steps of: preparing the cellulose produced by the gluconacetobacter strain according to claim 1; and impregnating the cellulose with a resin (Masaya Nogi and Hiroyuki Yano, Transparent Nanocomposites Based on Cellulose Produced by Bacteria Offer Potential Innovation in the Electronics Device Industry, Advanced materials 2008, pp 1849-1852).

BRIEF DESCRIPTION OF THE DRAWINGS

The above and other aspects, advantages and features of this disclosure will become more apparent by describing in further detail exemplary embodiments thereof with reference to the accompanying drawings, in which:

FIGS. 1 (a) and (b) show images observed by optical microscopy and scanning electron microscopy (SEM), respectively, of the morphological structure of the D44 strain disclosed herein.

FIGS. 2A, 2B, and 2C present a sequence alignment of 16s rDNA of D44 strain (upper sequence in FIGS. 2A, 2B, and 2C is SEQ ID NO:1) with 16s rDNA of Gluconacetobacter rhaeticus (lower sequence in FIGS. 2A, 2B, and 2C is SEQ ID NO:5, AY180961) in which the symbol “*” below the aligned sequences represents a position having identical nucleotides in the two aligned sequences.

FIG. 3 is a phylogenetic tree of gluconacetobacter, gluconobacter, acetobacter bacteria of the acetobacter family, including the D44 strain of the present invention.

FIG. 4 presents image of a culture flask showing cellulose formed by the D44 stain during culture in H.S. culture medium.

FIGS. 5 (a) and (b) show images observed by optical microscopy and scanning electron microscopy (SEM), respectively, of the morphological structure of the D47 strain disclosed herein.

FIGS. 6A, 6B, and 6C present a sequence alignment of 16s rDNA of D47 strain (upper sequence in FIGS. 6A, 6B, and 6C is SEQ ID NO:2) with 16s rDNA of Gluconacetobacter intermedius (lower sequence in FIGS. 6A, 6B, and 6C is SEQ ID NO:6, Y14694) in which the symbol “*” below the aligned sequences represents a position having identical nucleotides in the two aligned sequences.

FIG. 7 is a phylogenetic tree of gluconacetobacter, gluconobacter, acetobacter bacteria of the acetobacter family, including the D47 strain of the present invention.

FIG. 8 presents image of a culture flask showing cellulose formed by the D47 stain during culture in H.S. culture medium.

FIGS. 9A, and 9B present images of the cellulose produced by culturing D47 strain in H.S. medium (FIG. 9A) and coconut mixed medium (2) (FIG. 9B).

DETAILED DESCRIPTION OF THE EMBODIMENTS

The present invention is further explained in more detail below.

The present invention relates to novel gluconacetobacter strains having excellent cellulose producing activity. Specifically, the present invention provides a gluconacetobacter strain with excellent cellulose producing activity having gluconacetobacter sp. D44 strain having Accession No: KCCM11078P or gluconacetobacter intermedius D47 strain having Accession No: KCCM11079P.

A strain of the present invention is a species belonging to the acetobacteraceae family. Though not limited thereto, the strain of the present invention could be isolated from a vinegar class. Preferably, the strain could be isolated from persimmon vinegar, and more preferable, from the surface of persimmon vinegar.

According to one embodiment of the present invention, the strain having cellulose producing activity is isolated from the surface of persimmon vinegar, and the cellulose producing activity can be determined by any method known to those skilled in the art. For example, this includes, but is not limited to, inoculating H.S. culture medium (Table 1) with the strain disclosed herein to determine formation of cellulose at the air-liquid interface of the culture or inoculating Carr culture medium (Table 1) with the strain disclosed herein to determine a color transformation (Example 1).

The analysis of both morphological and biochemical characteristics of the strain of the present invention, shown in Table 2, and Table 3 (D44) and Table 4 (D47), respectively (Example 2), indicates that the strain is a gluconacetobacter strain.

In addition, the strains of the present invention was analyzed to determine whether it is a novel gluconacetobacter strain by obtaining its 16s rDNA sequence, shown in SEQ ID No: 1 and SEQ ID No: 2, respectively, and comparing the sequences to the 16s rDNA sequences of other known gluconacetobacter strains. The results showed that the 16s rDNA of the D44 strain disclosed herein showed the most homology to the 16s rDNA of Gluconacetobacter rhaeticus, however the percent homology was only 87.215%, and the 16s rDNA of the D47 strain disclosed herein showed the most homology to the 16s rDNA of Gluconacetobacter intermedicus, the percent homology was 99.776%. This indicates that the strains of the present invention is novel gluconacetobacter strains (Example 2).

The isolated and identified gluconacetobacter strains disclosed herein were deposited with the Korean Culture Center of Microorganisms (KCCM) on Mar. 26, 2010, and designated as Accession No: KCCM11078P and Accession No: KCCM11079P, respectively.

A culture of the gluconacetobacter strain of the present invention can be prepared using a culture medium and culture methods known in the art for their use in culturing microorganisms.

In culturing the gluconacetobacter strain of the present invention, culture media for microorganisms, specifically culture media for acetobacteraceae, and more specifically the culture media disclosed in Table 1 or Table 7 can be selected according to the desired objectives to be achieved. Most specifically, to produce cellulose, a culture medium for cellulose production, particularly, H.S. culture medium listed in Table 1 or coconut mixed medium (2) listed in Table 7, can be used (Example 4).

D44 strain can be preferably cultured either in H.S. medium comprising glucose 20 g/L, yeast extract 5 g/L, peptone 5 g/L, Na₂HPO₄ 2.7 g/L and sodium citrate 1.15 g/L or in coconut liquid medium consisting of undiluted coconut solution 100% (w/v). The yeast from the yeast extract (CAS No: 8013-01-02) (EINECS No: 232-387-9) contains no more than 40% of proteins, and can be gold and silver colored flake or powder with a physiochemical property of unique odor and no fermentability containing no more than 0.12 mg of thiamine hydrochloride per gram, no more than 0.04 mg of riboflavin and no more than 0.25 mg of nicotinic acid.

D47 strain can be preferably cultured in a medium comprising H.S. medium, coconut liquid medium or undiluted coconut solution, sugar, and ammonium sulphate. More preferably, the strain can be cultured in coconut mixed medium comprising undiluted coconut solution 85˜94.9 part by weight, sugar 5˜15 part by weight, and ammonium sulphate 0.1˜1 part by weight.

Ammonium sulphate refers to white crystal structured obtained by reacting sulfuric acid and ammonia, and ammonium sulphate with a purity of preferably, 10-99.9%, more preferably, 10-30% and most preferably 15-25% can be used.

A culture of the present invention can be prepared by inoculating the culture medium with the strain disclosed herein, or by any microorganism culturing method known to those skilled in the art, such as for example, but not limited to, stationary culture or spinner culture. Specifically, an acetobacteraceae culturing method can be used and, more specifically, the culture medium can be inoculated with the strain of the present invention at 1 weight % (based on the total weight of culture medium) and cultured for 4-7 days at 28˜30° C., most preferably at 30° C., to produce the culture.

Preferably, a culture of the present invention may contain cellulose produced by the strain of the present invention, but is not limited thereto.

A composition of the present invention for cellulose production comprises at least one selected from the group consisting of the gluconacetobacter strain disclosed herein, a culture thereof, and a concentrate or a dried product of the strain or the culture.

Since the strain of the present invention can produce cellulose in an efficient manner, the strain, a culture of the strain, a concentrate or a dried product of the strain or the culture are well suited for use as a composition for cellulose production.

A method of preparing a culture of the strain is described as the above. Specifically, this includes, but is not limited to, inoculation of a culture medium for cellulose production, or H.S. culture medium disclosed in Table 1, or coconut mixed medium (2) disclosed in Table 7, with the strain of the present invention. The culture can be produced specifically by for example, but is not limited to, a stationary culture or a spinner culture, and more specifically by stationery culture. A concentrate or a dried product of the strain or the culture thereof can be prepared according to any suitable method known to those skilled in the art for concentrating or drying microorganisms or a culture of microorganisms.

A composition for producing cellulose may contain at least one selected from the group consisting of the gluconacetobacter strain, a culture thereof, and a concentrate or a dried product of the strain or the culture, but is not limited thereto. Specifically, the composition may comprise at least one selected from the group consisting of the gluconacetobacter strain, a culture thereof, a concentrate or a dried product of the strain or the culture, for example, at 1 wt % of the composition.

A method for producing cellulose of the present invention includes culturing the gluconacetobacter strain disclosed herein, and obtaining cellulose from the culture. In some embodiments, culturing the gluconacetobacter strain D44 or D47 is performed under conditions such that cellulose is produced.

Culturing the strain may be carried out according to the method described above. In the method for producing cellulose, the cellulose formed during culturing of the strain of the present invention can be, for example, immersed in sodium hydroxide and purified by washing with distilled water, but is not limited thereto. The resultant cellulose can be, for example, in the form of a film (Example 3).

The cellulose produced by the strain of the present invention is characterized as having a smooth, firm and elastic surface, and a thickness of approximately 0.3-12 mm which is noticeably improved thickness compared to existing bacterial cellulose (Example 3 and Example 4). It is also classified as a nano-structured cellulose having a feature of a superb thermodynamic property.

Moreover, the strain of the present invention has excellent cellulose production activity. In particular, the strain can produce cellulose at a rate 3-97.5 times as efficient as acetobacter xylinum, a microorganism widely known for producing bacterial cellulose (Example 3 and Example 4).

The cellulose produced by the strain of the present invention, due to its superb thermodynamic property, can be characterized as nano-structured bacterial cellulose and therefore utilized as a bio-nano-fiber.

A method for producing a cellulose-based resin can include the steps of preparing cellulose produced by the gluconacetobacter strain; and impregnating the cellulose with a resin.

Impregnating the cellulose with a resin to produce the cellulose-based resin can be performed by a method known to those of skill in the art (Masaya Nogi and Hiroyuki Yano, Transparent Nanocomposites Based on Cellulose Produced by Bacteria Offer Potential Innovation in the Electronics Device Industry, Advanced materials 2008, pp 1849-1852). This includes, for example, but is not limited to, mixing the cellulose produced by the gluconacetobacter strain of the present invention with a thermoplastic resin and a bonding agent, and thereafter extruding the resultant mixture.

The thermoplastic resin can preferably be selected from the group consisting of polypropylene, polyethylene, polystyrene, and polyvinylchloride. The bonding agent can preferably comprise at least one selected from the group consisting of maleate ethylene, maleate propylene, and silane. At least one additive selected from the group consisting of stabilizer, pigment, dye, inorganic/organic additives, and electromagnetic shielder or a mixture thereof, can be additionally included in the mixture containing the cellulose, thermoplastic resin, and bonding agent.

The cellulose-based resin prepared according to the method described above contains nano-structured bacterial cellulose having an excellent thermodynamic property, which allows the resin to be adapted for the use as a substrate material for liquid crystal display (LCD).

Accordingly, the present invent ion relates to a method of producing a cellulose-based resin and provides a method of producing LCD substrate comprising the steps of producing a cellulose-based resin; and producing a LCD substrate using the cellulose-based resin.

In addition, the present invention provides a LCD substrate using the cellulose-based resin.

It has been reported that cellulose produced by bacteria protects the cells from any lethal effect caused by UV light, and allows the formation of bacterial cluster, which in turn promotes shielding effect from the competitors who share the same nutrient source as well as moisturization of the cell.

Characteristics of the bacterial cellulose, including high crystallization ability and high water absorption, allow for its application in diverse industrial areas, such as in a speaker vibration pad. Furthermore, the bacterial cellulose in its gel state feels pleasant to the skin and easily integrates with the outer skin. Bacterial cellulose made by the strain disclosed herein can be made into a medical or a cosmetic pad (for example, a facial mask sheet) or an artificial skin because of its ability of retaining ingredients and moisture on the epidermis. Moreover, it has been reported that when a cellulose membrane is treated with 5% NaOH or 0.5% NaCl to remove components other than cellulose and the product thereof is pressurized, a membrane having high elasticity is formed. Such a membrane, for example, is used as a speaker vibration pad in a high-performance headset manufactured by Sony in Japan.

The solidity and elasticity of paper containing bacterial cellulose are enhanced by 2.5 fold relative to the control group. In comparison with a synthetic fiber, a sheet with better qualities including superior solidity, heat stability, and structural stability can be achieved if 5-20% of the cellulose is added to a synthetic polymer fiber, aromatic polyamide or polyamide staple fiber. When a mixture containing cellulose and a synthetic or glass fiber is constructed as a sheet, it can also be used as an air filter, a wiring substrate for a printer, or a floor material.

The cellulose produced by the microorganism of the present invention is diversely applicable as an industrial and dietary material, especially considering the fact that it is environment-friendly (Jeong., Y. J., Lee., I. S. A view of utilizing cellulose produced by acetobacter bacteria. Food Industry and Nutrition, Vol. 5, pp. 25-29, 2000).

Due to its superb thermodynamic properties, the cellulose produced by the strain of the present invention, which is characterized to be nano-structured bacterial cellulose, can be utilized as a bio-nano-fiber. Particularly, the cellulose can be impregnated with a resin to produce a cellulose-based resin, which can be effectively used as a substrate material for LCD.

The present invention is further explained in more detail with reference to the following examples. These examples, however, should not be interpreted as limiting the scope of the present invention in any manner.

REFERENCE EXAMPLE 1 Culture Media Used in the Experiment and Culturing Conditions

In order to isolate and identify the novel strain disclosed herein, the culture media listed in Table 1 were used. Unless stated otherwise in the example below, the novel strain disclosed herein was cultured using the culture medium for 7 days at 30° C.

TABLE 1 Types of culture media and their compositions Culture medium Composition Related Literature H.S Glucose 20 g/L Schraamm, M. and S. Hestrin. 1054. Factors culture Yeast extract 5 g/L, affecting production of cellulose at the air/liquid medium Peptone 5 g/L, interface of a culture of Acetobacter Na2HPO4 2.7 g/L, xylinum. J. Gen. Microbiol. 11: 123-129. sodium citrate 1.15 g/L, pH 5.0 GYC Glucose 50 g/L, Jang, O. Y., Joo, K. H., Lee, J. H., Baik, C. G., Growth culture Yeast extract 10 g/L, Characteristics and Production of Celulose of medium Calcium Carbonate Microorganisms in Static Culture Vinegar. Korean 30 g/L, and Agar J. Food Sci. Tech., Vol. 35, No. 6, 25 g/L pp. 1150~1154(2003) Frateur Ethanol 30 ml/L, Krig, N. R., J. G. Holt. 1984. Bergey's Manual of culture Yeast Extract 10 g/L, Systematic Bacteriology Vol. 1. The William and medium Peptone 10 g/L Wilkins Co., U.S.A., pp. 267-277. Calcium Carbonate 10 g/L and Agar 20 g/L Carr Yeast Extract 30 g/L, Krig, N. R., J. G. Holt. 1984. Bergey's Manual of culture Ethanol 20 ml/L, Systematic Bacteriology Vol. 1. The William and medium Bromocresol purple Wilkins Co., U.S.A., pp. 267-277. 0.022 g/L, Agar 20 g/L, pH 6.0 YEG Yeast Extract 10 g/L, Jang. O. Y., Joo. K. H., Lee. J. H., Baik. C. G. 2003. Solid Glycerol 30 g/L, Growth characteristics and production of culture Agar 20 g/L cellulose of microorganisms in static culture medium vinegar. Korean J. Food Sci. Tech. vol. 35, No. 6, pp. 1150~1154. SM Yeast Extract 5 g/L, Jang. O. Y., Joo. K. H., Lee. J. H., Baik. C. G. 2003. culture Glucose 50 g/L Growth characteristics and production of medium cellulose of microorganisms in static culture vinegar. Korean J. Food Sci. Tech. vol. 35, No. 6, pp. 1150~1154. YPC Yeast extract 5 g/L, Jang. O. Y., Joo. K. H., Lee. J. H., Baik. C. G. 2003. culture Peptone 5 g/L, Growth characteristics and production of medium Calcium carbonate cellulose of microorganisms in static culture 5 g/L vinegar. Korean J. Food Sci. Tech. vol. 35, No. 6, pp. 1150~1154. GYP Glucose 30 g/L, Jang. O. Y., Joo. K. H., Lee. J. H., Baik. C. G. 2003. culture Yeast Extract 5 g/L, Growth characteristics and production of medium Peptone 2 g/L cellulose of microorganisms in static culture vinegar. Korean J. Food Sci. Tech. vol. 35, No. 6, pp. 1150~1154.

EXAMPLE 1 Isolation of Novel Strain Producing Cellulose EXAMPLE 1-1 Isolation of Gluconacetobacter D44 Strain

The strain disclosed herein was isolated from the surface of traditional persimmon vinegar (Jeonbuk Wanju-gun Bongdong-eup Yulso-ri, South Korea). Specifically, various regions of the persimmon vinegar were extracted, and designated as A, B, C, and D according to the extracted region. D was a sample obtained from the surface of the persimmon vinegar.

100 ml H.S. culture medium was inoculated with 1% of an undiluted solution of the persimmon vinegar samples A, B, C, or D and cultured for 7 days at 30° C. Upon completion of culturing, a homogeneous strain from sample D which produced cellulose at the air-liquid interface of the H.S. culture medium was diluted at a concentration of 10⁻⁷ and smeared over a solid H.S. culture medium. Liquid H.S. culture medium was inoculated with randomly selected colonies from the solid H.S. culture. Among these, the strain that formed cellulose at the air-liquid interface of the culture medium was selected and isolated.

Carr culture medium containing bromocresol purple having a discoloration range of pH 5.2-6.8 was also inoculated with the strain isolated from the D portion of the persimmon vinegar and then tested to see if there were color transformations from yellow to purple and from purple to yellow. Such color transformations demonstrate that the strain has a oxidation pathway which oxidizes ethanol to acetic acid and reoxidizes to carbon dioxide and water. These results confirm that the strain showed cellulose production activity (Jang. O. Y., Joo. K. H., Lee. J. H., Baik. C. G. 2003. Growth characteristics and production of cellulose of microorganisms in static culture vinegar. Korean J. Food SCI. tech. vol. 35, No. 6, pp. 1150-1154).

The strain that showed cellulose production activity was designated as the “D44” strain.

EXAMPLE 1-2 Isolation of Gluconacetobacter intermedius D47 Strain

The strain disclosed herein was isolated from the surface of traditional persimmon vinegar (Jeonbuk Wanju-gun Bongdong-eup Yulso-ri, South Korea). Specifically, the epithelium that comes out when producing the traditional persimmon vinegar was obtained from Nong-Hyup (South Korea), and was sufficiently cut with a sterilized scissor for dissection. Then, the small amount was inoculated into H.S. medium and cultured for 7 days at 30° C. Upon completion of culturing, a homogeneous strain from sample which produced cellulose at the air-liquid interface of the H.S. culture medium was diluted at a concentration of 10⁻⁷ and smeared over a solid H.S. culture medium. Liquid H.S. culture medium was inoculated with randomly selected colonies from the solid H.S. culture. Among these, the strain that formed cellulose at the air-liquid interface of the culture medium was selected and isolated.

Carr culture medium containing bromocresol purple having a discoloration range of pH 5.2-6.8 was also inoculated with the strain isolated from the surface of the persimmon vinegar and then tested to see if there were color transformations from yellow to purple and from purple to yellow. Such color transformations demonstrate that the strain has a oxidation pathway which oxidizes ethanol to acetic acid and reoxidizes to carbon dioxide and water. These results confirm that the strain showed cellulose production activity (Jang. O. Y., Joo. K. H., Lee. J. H., Baik. C. G. 2003. Growth characteristics and production of cellulose of microorganisms in static culture vinegar. Korean J. Food SCI. tech. vol. 35, No. 6, pp. 1150-1154).

The strain that showed cellulose production activity was designated as the “D47” strain.

EXAMPLE 2 Identification and Deposit of Novel Strain Producing Cellulose EXAMPLE 2-1 Morphological Features

The size, shape, Gram staining, colony shape, and colony color of the D44 strain and the D47 strain selected and isolated in Example 1 were studied, respectively. Specifically, the colonies of D44 strain and D47 strain were examined in GYC culture medium and the cellulose produced by the D44 and D47 were observed in the presence of the bacteria by optical microscopy and scanning electron microscopy (SEM).

More specifically, an optical microscope (Nikon ECLIPSE E600, Japan) was used to identify the each strain morphology and Gram staining. Furthermore, SEM was used to identify the size of the bacteria and the cellulose fiber produced thereby. Particularly, SEM was performed using the modified Chae's method (Chae. C. M. 1977. Maceration methods for SEM observation ‘A legal medicine lecture room’. Kyungpook National University. p 40-58). The D44 and the D47 bacterial bodies were pre-fixed with 2% (v/v) Glutaraldehyde for 2 hr, post-fixed with 2% (w/v) OsO₄ for 2 hr, and then dehydrated with ethanol. After treating with isoamyl acetate, the resultant was dried at 55° C., followed by coating with gold. The results are shown in Table 2, FIG. 1, and FIG. 5.

TABLE 2 Morphological features of D44 strain and D47 strain Morphological Characteristic D44 D47 Gram Staining Negative Negative Cell Shape Rod-shaped Rod-shaped (bacillus) (bacillus) Cell size(μm) 0.5 × 1.8 μm 0.6~0.8 × 1.6~2.0 um Spore Formation Negative Negative Colony Shape Convex Convex Colony Color White Pale Yellow Colony Surface Smooth and Rough Smooth and Rough Colony Transparency Opaque Opaque

As described in Table 2, FIG. 1 and FIG. 5, the D44 and the D47 strains are Gram negative, do not form a spore, and can be solitary or a pair (a diplobacilli). Specifically, as shown in FIG. 1 and FIG. 5, the strains exist inside the cellulose produced by the D44 and the D47 strain.

EXAMPLE 2-2 Biochemical Features

In order to examine the biochemical features of the D44 and the D47 strains, the strains were cultured in H.S. liquid culture medium respectively and the extracted bacterial liquid was sub-cultured in a new culture medium.

Specifically, the novel D44 and D47 strains of the present invention were cultured in Frateur culture medium and then the ethanol oxidation path was identified by determining the neutralization of CaCO₃ in the culture medium.

In order to examine ketogenesis in glycerol after culturing the bacteria on YEG solid culture medium for 5 days at 30° C., a few drops of Fehlings solution was applied over the colony to check whether there was an orange color transformation.

Furthermore, to examine strain growth and cellulose production in the presence of ethanol and sodium chloride, growth of the D44 strain was observed in SM culture medium with 0.5% (w/v), 1.0% (w/v), 1.5% (w/v), or 2.0% (w/v) sodium chloride added or 10% (v/v) ethanol added, followed by stationary culturing for 7 days at 30° C.

In addition, the D44 and the D47 strain were smeared over GYC solid culture medium followed by culturing for 7 days at 30° C., and subsequently brown pigment formation was examined. In order to determine the formation of γ-pyrone, the bacteria was cultured on solid YPC culture medium containing 50 g/L glucose and 50 g/L fructose for 7 days at 30° C., and then a 5% (w/v) ferric chloride solution was dropped onto the culture. Formation of γ-pyrone by the strain using the glucose and fructose is indicated by a color transformation to purple. (Jang. O. Y., Joo. K. H., Lee. J. H., Baik. C. G. 2003. Growth characteristics and production of cellulose of microorganisms in static culture vinegar. Korean J. Food Sci. Tech. vol. 35, No. 6, pp. 1150-1154).

To see the resistance of the D44 and the D47 strain against acetic acid, the D44 and the D47 strain were grown in GYP culture medium in which acetic acid concentration was adjusted to 2% (v/v)˜10% (v/v), followed by culturing for 7 days at 30° C.

Additional biochemical experiments to identify the strain were performed using an API 20NE kit (Bio-Merieux, France). The strain was identified from the results using Bergy's Manual of Systematic Bacteriology (Krig, N. R., J. G. Holt. 1984. Bergey's Manual of Systematic Bacteriology Vol. 1. The William and Wilkins Co., U.S.A.).

These experimental results (summarized in Table 3 and Table 4) were compared to an acetobacter strain (Acetobacter xylinum, KCCM40274), a gluconobacter strain (Gluconobacter oxidans, KCCM21183) and a gluconacetobacter strain. The gluconacetobacter strain (Gluconacetobacter persimmonensis, KJ145) was disclosed in Lee. et al. (Lee. O. S., Jang. S. Y., Jeong. Y. J. 2002. Effect of Ethanol on the Production of Cellulose and Acetic Acid by Gluconacetobacter persimmonensis KJ145. J. Korean Soc. Food Sci. Nutr. 31 (4). 572-577.)

TABLE 3 Biochemical features of D44 strain Acetobacter Gluconobacter Gluconacetobacter xylinum oxidans persimmonensis Feature D44 KCCM40274 KCCM21183 KJ145 Overoxidation + ¹⁾ +  − ²⁾ + of ethanol Ketogenesis + + + + from glycerol Oxidation of + + − + acetate to CO₂ and H₂O Oxidation of − + − + lactate to CO₂ and H₂O Oxidation of + ND Fructose to CO₂ and H₂O Brown − + − − pigmentation on GYC agar Cellulose + + − + formation Oxidase − − − − Indole − − − − production Urease − − − − γ-pyrone from − − + − 5% glucose γ-pyrone from − − + − 5% fructose β-galactocidase + + − + Nitrate to nitrite + + + − Gelatin − − − − liquefaction Acid produced from Arabinose − − − + Manose − ± + + Manitol + + + + Glucose + + + + Growth in the presence of 10% ethanol − − − − 0.5% NaCl +  ND ³⁾ 1.0% NaCl + 1.5% NaCl + 2.0% NaCl + 2%^(~)10% acetate − ¹⁾ +: Positive, ²⁾ −: Negative, ³⁾ ND: Not Decided

As shown in Table 3, as a result of inoculating Frateur culture medium with the novel D44 strain, CaCO₃ inside the culture medium was neutralized, forming a clear zone. The CaCO₃ re-precipitated 12 days after culturing. Accordingly, the D44 strain oxidates ethanol to acetic acid, and acetic acid to CO₂ and H₂O. (Son. H. J., Kim. K. K., Kim. H. S., Kim. Y. G. 1999. Isolation and identification of cellulose-producing bacteria. J. Agri. Tech & Dev. Inst., Vol. 28, No. 3, 134-138).

Moreover, the D44 strain cannot form γ-pyrone using 5% (w/v) glucose and 5% (w/v) fructose and showed a positive response to the ketogenesis reaction from glycerol. The D44 strain is β-galactosidase positive, oxidates nitrate to nitrite, and oxidates acetate, glucose, fructose, and mannitol, but cannot oxidate lactate.

Furthermore, the D44 strain showed negative responses with respect to indole production, urease, and the gelatin liquefaction reaction. The D44 strain is able to grow and develop in 0.5, 1.0, 1.5, or 2.0% (w/v) sodium chloride, and can produce cellulose in 0.5% sodium chloride. It was observed, however, that the D44 strain showed no tolerance for and was not able to grow at 2% (v/v)-10% (v/v) acetate concentration. Instead of forming a brown pigment, D44 produced only a transparent, white colony.

Based on the results described above, the D44 strain disclosed herein is determined to be a gluconacetobacter strain.

TABLE 4 Biochemical features of D47 strain Acetobacter Gluconobacter xylinum oxidans Features D47 KCCM40274 KCCM21183 Gluconacetobacter Overoxidation + ¹⁾ +  − ²⁾ + of ethanol Ketogenesis − + + + from glycerol Oxidation of + + − + acetate to CO₂ and H₂O Oxidation of − + − + lactate to CO₂ and H₂O Oxidation of + ND Fructose to CO₂ and H₂O Brown ± + − − pigmentation on GYC agar Cellulose + + − + formation Oxidase − − − − Indole − − − − production Urease − − − − γ-pyrone from − − + − 5% glucose γ-pyrone from − − + − 5% fructose β-galactocidase − + − + Nitrate to nitrite − + + − Gelatin − − − − liquefaction Acid produced from Arabinose − − − + Manose − ± + + Manitol + + + + Glucose + + + + Growth in the presence of 10% ethanol − − − − 0.5% NaCl +  ND ³⁾ 1.0% NaCl + 1.5% NaCl + 2.0% NaCl + 2~10% acetate − ¹⁾ +: Positive, ²⁾ −: Negative, ³⁾ ND: Not Decided

As shown in Table 4, as a result of inoculating Frateur culture medium with the novel D47 strain, CaCO₃ inside the culture medium was neutralized, forming a clear zone. The CaCO₃ re-precipitated 8 days after culturing. Accordingly, the D47 strain oxidates ethanol to acetic acid, and acetic acid to CO₂ and H₂O. (Son. H. J., Kim. K. K., Kim. H. S., Kim. Y. G. 1999. Isolation and identification of cellulose-producing bacteria. J. Agri. Tech & Dev. Inst., Vol. 28, No. 3, 134-138.)

Moreover, the D47 strain cannot form γ-pyrone using 5% (w/v) glucose and 5% (w/v) fructose and unlike the D44 strain, showed a negative response to the ketogenesis reaction from glycerol. And the D47 strain is β-galactosidase negative, does not oxidate nitrate to nitrite. However, similar to the D44 strain, the D47 strain oxidates acetate, glucose, fructose, and mannitol, but cannot oxidate lactate.

Furthermore, the D47 strain showed negative responses with respect to indole production, urease, and the gelatin liquefaction reaction. The D44 strain is able to grow and develop in 0.5, 1.0, 1.5, or 2.0% (w/v) sodium chloride, and can produce cellulose in 0.5% sodium chloride. It was observed, however, that the D47 strain showed no tolerance for and was not able to grow at 2% (v/v)-10% (v/v) acetate concentration. Unlike the D44 strain, the D47 strain produced a pale brown colony.

Based on the results described above, the D47 strain disclosed herein is determined to be a gluconacetobacter strain.

EXAMPLE 2-3 16s rDNA Analysis

In order to extract ribosomal DNA (rDNA) from the isolated D44 and D47 strains in Example 1, 1% (v/v) cellulase (Celluclast, nonzyme) was added to a D44 culture to remove cellulose formed on the air-liquid interface of the H.S. culture medium, and the mixture was cultured with agitation for 1 hr at 37° C. 16s rDNA was extracted and amplified using a DNeasy Blood & Tissue kit (QIAGEN, Germany). A complete sequence of the 16s rDNA of the D44 strain (SEQ ID NO: 1) and a complete sequence of the 16s rDNA of the D47 strain (SEQ ID NO: 2) were obtained by sequencing.

For cloning of the 16s rDNA of the D44 and D47 strains, polymerase chain reaction (PCR) amplification was performed using SEQ ID NO: 3 (5′-AGAGTTTGATCMT GGCTCAG-3′(Forward)) and SEQ ID NO: 4 (5′-ACGGGCGGGTGTGTRC-3′(Reverse)) as the primer pair.

In particular, the PCR amplification was performed through 35 cycles consisting of denaturing for 30 sec at 95° C., annealing for 30 sec at 58° C., and extending for 90 sec at 72° C. with a Biometra thermocycler using 100 ng template DNA, 0.5 uM primer DNA, 0.2 mM dNTPs, 10× EX TAQ buffer solution, and 0.025 U/ul Taq polymerase (TaKaRa Bio Inc., Japan). The PCR product was detected by 1% agarose gel electrophoresis, and subsequently purified with a PCR purification kit (Bioneer, Korea) followed by cloning into a pGEM T-easy vector (Promega, U.S.A) by T4 ligase (Promega, USA). The nucleic acid sequence information of the 16s rDNA of the D44 and the D47 strains were obtained by sequencing.

For identification reference, the homology of the D44 and the D47 16s rDNA sequence to that of ribosomal DNAs recorded in GenBank was examined. Using the computer programs Bioedit (a biological sequence alignment editor written by Tom Hall and available free on the internet), Clustal X (Jeanmougin F, Thompson J D, Gouy M, Higgins D G, Gibson T J. (1998). Multiple sequence alignment with Clustal X. Trends Biochem Sci., 23, 403-405), and MEGA (Kumar S, Dudley J, Nei M & Tamura K (2008) MEGA: A biologist-centric software for evolutionary analysis of DNA and protein sequences. Briefings in Bioinformatics 9: 299-306.) a phylogenetic tree of similarly identified microorganisms was drawn to observe the relationship among similar species.

The comparison of the rDNA sequence of the D44 strain to 16s rDNA sequence (AY180961) of Gluconacetobacter rhaeticus showed that the percentage of homology was limited to 87.215%. Usually, 98-99% homology of two sequences is required to conclude that the bacteria belong to the same strain. Since the homology ratio between the D44 strain and Gluconacetobacter rhaeticus, however, was only 87.215%, the D44 strain disclosed herein is a novel gluconacetobacter strain.

Moreover, as shown in FIG. 2A-2C, the homology of D44 and Gluconacetobacter rhaeticus was confirmed with Clustal X. The homology percentage of D44 and Gluconacetobacter rhaeticus was limited to 87.215%.

Bioedit, Clustal X, and MEGA were used to examine the phylogenetic relationship of D44 and microorganisms belonging to the identical family, acetobacteraceae. Specifically, as shown FIG. 3, a phylogenetic tree of gluconacetobacter, gluconobacter, acetobacter bacterial strains was prepared by applying a Neighbor-joining method.

The comparison of the rDNA sequence of the D47 strain to 16s rDNA sequence (Y14694) of Gluconacetobacter intermedius showed that the percentage of homology was 99.774%. Accordingly, the D47 strain is concluded to be analogous bacteria and was designated to be gluconacetobacter intermedius D47.

Moreover, as shown in FIG. 6A-6C, the homology of D47 and Gluconacetobacter intermedius was confirmed with Clustal X. The homology percentage of D47 and Gluconacetobacter intermedius was 99%.

As shown in Table 4 of Example 2-2, however, the D47 strain, unlike traditional gluconacetobacter strain, showed dihydroxyacetone forming ketogenesis reaction in glycerol, was not able to oxidate lactate, and produced cellulose on the medium surface during culturing in H.S. medium added with 0.5% (w/v) NaCl. These results confirm that D47 is a novel gluconacetobacter strain having biochemical features that are completely different from the traditional gluconacetobacter. In terms of cellulose producing ability, the D47 also showed prominently higher producing activity compared to traditional gluconacetobacter strain as discussed more in detail below.

Bioedit, Clustal X, and MEGA were used to examine the phylogenetic relationship of D47 and microorganisms belonging to the identical family, acetobacteraceae. Specifically, as shown FIG. 7, a phylogenetic tree of gluconacetobacter, gluconobacter, acetobacter bacterial strains was prepared by applying a Neighbor-joining method.

EXAMPLE 2-4 Deposit of the D44 and the D47 Strains

Each of the novel, isolated and identified Gluconacetobacter strains disclosed herein were deposited at the Korean Culture Center of Microorganisms (KCCM) on Mar. 26, 2010 and received Accession No: KCCM11078P(D44) and Accession No: KCCM11079P(D47).

EXAMPLE 3 Cellulose Producing Activity of Strain of the Present Invention EXAMPLE 3-1 Cellulose Producing Activity of Strain of the Present Invention

Cellulose production by the D44 and the D47 strains were examined in H.S. culture medium and the result is shown in FIG. 4 and FIG. 8.

As shown in FIG. 4 and FIG. 8, after culturing for 2-3 days, the D44 and the D47 strains extruded cellulose at the air-liquid interface of the culture. As extruded cellulose accumulated as the culturing period extended, the culture thickened.

After inoculating H.S. culture medium with each of the D44 and the D47 strains at 1 weight % (based on the total weight of culture medium), and stationary culturing for 7 days at 30° C., the dry weight of the cellulose produced was measured (Table 5 and FIG. 9A). Specifically, upon completion of stationary culturing, the cellulose formed at the air-liquid interface of the H.S. culture medium was collected, washed with tap water, and then inserted into a small quantity of 0.1N NaOH which was boiled for 1 hr prior to cell lysis. The collected cellulose was re-washed with tap water and neutralized by inserting into a small quantity of distilled water for 1 day. The neutralized cellulose was filtered, dehydrated at 90° C. until it reached a constant weight, cooled in desiccators, and then the dry weight was measured.

TABLE 5 Dry weight of cellulose (BC) produced by D44 and D47 strains BC production(Dry weight, g/L) D44 1.70 ± 0.91 D47 2.17 ± 0.37

The cellulose produced by the D44 strain disclosed herein and treated as described above had a smooth, firm, and elastic surface and a thickness of approximately 0.3 mm. The cellulose produced by the D47 strain disclosed herein and treated as described above had a smooth, firm, and elastic surface and a thickness of approximately 4 mm. Furthermore, the D47 strain showed much higher cellulose producing activity. As discussed more in detail below, the thickness of cellulose produced by D47 strain in coconut mixed medium (2) was approximately 12 mm and showed prominently higher cellulose producing activity.

EXAMPLE 3-2 Comparison of Cellulose Producing Activity of Strain of the Present Invention

The cellulose producing activity each of the D44 and D47 strains were compared to that of Acetobacter xylinum, a microorganism well known for cellulose production.

H.S. culture medium was inoculated with each of the D44 and D47 strain or Acetobacter xylinum KCCM 40274 at 1 weight % (based on the total weight of the culture medium), and subjected to stationary culture for 7 days at 30° C. The dry weight of cellulose produced by each was measured as described in Example <3-1>. The results are shown in Table 6.

TABLE 6 Dry weight of cellulose (BC) produced by D44 and D47 strains or Acetobacter xylinum KCCM 40274 Acetobacter xylinum Gluconacetobacter Gluconacetobacter KCCM 40274 sp. D44 intermedius D47 BC yield 0.50 ± 0.28 1.70 ± 0.91 2.17 ± 0.37 (g/L)

As shown in Table 6, the D44 strain disclosed herein can produce approximately three times as much cellulose as the Acetobacter xylinum, and the D47 strain disclosed herein can produce approximately 4.34 times as much cellulose as the Acetobacter xylinum. It is noteworthy that the D47 strain showed approximately 1.27 times as much cellulose producing activity as the D44 strain.

REFERENCE EXAMPLE 2 Mediums Used for Evaluation of Cellulose Production and Culturing Conditions Based on Medium Composition

In order to determine the effect of medium composition, one of the factors that promotes cellulose production by the strains disclosed herein in H.S. medium, bacteria was cultured in the medium prepared by composition described in Table 7.

Bacteria culturing solution was adjusted to be 1% (v/v) and the temperature was maintained to be 30° C. Upon 7 days culturing, the dry weight was measured and average value obtained through repeated experiments was used.

TABLE 7 Medium composition for culturing D44 and D47 strains Coconut Coconut Coconut Medium H.S liquid mixed mixed composition medium medium medium(1) medium(2) Glucose 20 g/L — — — Yeast Extract 5 g/L — — — (difco, USA) Peptone 5 g/L — — — Na₂HPO₄ 2.7 g/L — — — Sodium citrate 1.15 g/L — — — Undiluted coconut — 1000 g/L 895 g/L 895 g/L solution¹⁾ Sugar — — 100 g/L 100 g/L Ammonium — — 5 g/L — Sulfate²⁾ Ammonium — — — 5 g/L Sulfate³⁾ pH, temperature 5, 30 5, 30 5, 30 5, 30 (° C.) ¹⁾Undiluteed coconut solution: 100% undiluted solution imported from www.onedrinks.com (One world enterproses, LLC, USA. mede in brazil) ²⁾Ammonium Sulfate: purity of 99% ammonium sulfide manufactured by Sigma(USA) ³⁾Ammonium Sulfate: purity of 21% ammonium sulfide manufactured by Chia Tai Co., Ltd. (Thailand)

EXAMPLE 4 Experiment for Promoting Cellulose Producing Activity by the Strains of the Present Invention Depending on Medium Composition

As shown in Table 7, the medium composition varied to measure the dry weight and thickness of the cellulose produced by the D44 and the D47 strains disclosed herein and the results were listed in Table 8. The results were compared to Actobacter xylinum strain (KCCM40274) used in Example 3-2.

TABLE 8 Comparison of dry weight of cellulose production based on medium composition Dry Weight Strain Medium (g/L) Acetobacter xylinum H.SMedium 0.10 (KCCM 40274) Coconut Liquid Medium 0.02 Coconut Mixed Medium(1) 0.20 Coconut Mixed Medium(2) 0.20 Gluconactetobacter sp. D44 H.SMedium 1.90 Coconut Liquid Medium 1.00 Coconut Mixed Medium(1) 0.20 Coconut Mixed Medium(2) 0.20 Gluconacetobacter H.SMedium 2.20 intermedius D47 Coconut Liquid Medium 1.95 Coconut Mixed Medium(1) 0.80 Coconut Mixed Medium(2) 5.10

As shown in Table 8, the D44 and the D47 strains disclosed herein generally showed much higher cellulose production yield compared to acetobacter xylinum, a representative strain for producing cellulose. Especially, the D47 strain produced the greatest amount of cellulose in all mediums.

Specifically, the dry weight of cellulose produced by the D44 strain was 19 times as much in H.S. medium and 50 times as much in coconut liquid medium as the acetobacter xylium strain. The dry weight of cellulose produced by D47 strain was 22 times as much in H.S. medium and 97.5 times as much in coconut liquid medium as the acetobacter xylium strain. These results confirm that the strain of the present invention produced cellulose with much higher yield.

Meanwhile, the comparison of cellulose production yield between acetobacter xylium strain and the D44 showed no significant difference in coconut mixed medium (1), (2). However, the D47 strain disclosed herein showed the dry weight of produced cellulose was 0.80 g/L in coconut mixed medium (1), and 5.10 g/L in coconut mixed medium (2). When compared to acetobacter xylium strain, each of these figures are 4 times and 25.5 times higher in coconut mixed medium (1), (2), respectively. The result further confirms that the D47 strain produces cellulose with higher yield than the D44 strain.

In conclusion, the strains disclosed herein can produce cellulose with much higher yields relative to acetobacter xylium, a representative strain for producing cellulose, and such cellulose producing efficiency can be varied depending on medium composition.

In other words, whereas the D44 strain produced 9.5 times as much cellulose in H.S. medium as the cellulose in coconut mixed medium, D47 strain produced 2.32 times as much cellulose in coconut mixed medium (2) prepared by adding sugar and ammonium sulphate into undiluted coconut solution, and 6.4 times as much cellulose in coconut mixed medium (1) as the cellulose in H.S. medium. Moreover, the measurement of thickness of cellulose produced by D47 strain in coconut mixed medium (2) showed that significantly increased thickness of 12 mm, which was 3 times thicker than 4 mm measured in H.S. medium, could be observed (FIGS. 9A and 9B). 

1. An isolated gluconacetobacter strain designated with Accession No: KCCM11078P, and having cellulose producing activity.
 2. The gluconacetobacter strain according to claim 1, wherein the strain having Accession No: KCCM11078P has the 16s rDNA nucleotide sequence of SEQ ID No:
 1. 3. A culture of the gluconacetobacter strain according to claim
 1. 4. The culture according to claim 3 wherein said culture comprises cellulose.
 5. A composition for cellulose production comprising at least one selected from the group consisting of the gluconacetobacter strain according to claim 1, a culture thereof, a concentrate of the strain or the culture, and a dried product of the strain or the culture.
 6. A method for producing cellulose comprising the steps of: culturing the gluconacetobacter strain according to claim 1; and obtaining cellulose from the culture.
 7. The method according to claim 6, wherein the culturing step of glucoacetorbacter strain having Accession No: KCCM11078P is performed in H.S. medium comprising glucose 20 g/L, yeast extract 5 g/L, peptone 5 g/L, Na2HPO4 2.7 g/L and sodium citrate 1.15 g/L.
 8. A method for producing a cellulose-based resin comprising the steps of: preparing the cellulose produced by the gluconacetobacter strain according to claim 1; and impregnating the cellulose with a resin.
 9. The method according to claim 8, wherein the cellulose-based resin is adapted for a substrate of liquid crystal display (LCD). 